Spin injection assisted magnetic recording

ABSTRACT

A spin injection assisted magnetic recording structure is disclosed wherein a ferromagnetic (FM) layer and at least one spin preservation (SP) layer are formed between a main pole (MP) trailing side and a write shield (WS). Current (Ia) flows between the MP and WS, or is injected into the FM layer. As a result, the spin polarized electrons from the FM layer, which flow across one or two SP layers to generate a magnetization that enhances one or both of a local WS magnetization and return field, and a local MP magnetization and write field, respectively. A lead to the FM layer may be stitched to enable lower resistance and improve reliability. The FM layer may be recessed from the ABS to allow more overlap with the SP layer for lower current density while maintaining performance. Higher linear density and area density capability, and better reliability are achieved.

RELATED PATENT APPLICATIONS

This application is related to the following: U.S. Pat. Nos. 10,325,618; and 10,424,326; assigned to a common assignee, and herein incorporated by reference in their entirety.

TECHNICAL FIELD

The present disclosure relates to a design for a spin injection assisted magnetic recording structure wherein a ferromagnetic (FM) layer adjoins one or two spin preserving (SP) layers in a write gap (WG), and a current is injected across the FM layer and at least one SP layer, and into one or both of a main pole (MP) and write shield (WS) to improve a local magnetic field and field gradient at one or both of a MP/WG interface and a WG/WS interface, respectively, thereby increasing linear density capability and area density capability (ADC) for perpendicular magnetic recording (PMR) applications.

BACKGROUND

As the data areal density in hard disk drive (HDD) writing increases, write heads and media bits are both required to be made in smaller sizes. However, as the write head size shrinks, its writability degrades. In particular, perpendicular magnetic recording (PMR) performance is limited by the saturation magnetization (Ms) of available magnetic materials. To improve writability, new technology is being developed that assists writing to a media bit. Two main approaches currently being investigated are thermally assisted magnetic recording (TAMR) and microwave assisted magnetic recording (MAMR). The latter is described by J-G. Zhu et al. in “Microwave Assisted Magnetic Recording”, IEEE Trans. Magn., vol. 44, pp. 125-131 (2008). MAMR uses a spin torque device to generate a high frequency field that reduces the coercive field of a medium bit thereby allowing the bit to be switched with a lower main pole field. A third approach called STRAMR (spin torque reversal assisted magnetic recording) relies on spin torque to reverse a magnetization in a flux generating layer (FGL) in the write gap to increase reluctance and force more magnetic flux from the MP at the ABS. STRAMR is described in U.S. Pat. No. 6,785,092.

Spin transfer (spin torque) devices are based on a spin-transfer effect that arises from the spin dependent electron transport properties of ferromagnetic-spacer-ferromagnetic multilayers. When a spin-polarized current passes through a FM1/NM/FM2 multilayer in a CPP (current perpendicular to plane) configuration where FM1 and FM2 are first and second FM layers and NM is a non-magnetic spacer, the spin angular moment of electrons from FM1 that is incident on FM2 interacts with magnetic moments of FM2 near the NM/FM2 interface. Through this interaction, the electrons transfer a portion of their angular momentum to FM2. As a result, spin-polarized current can switch the FM2 magnetization direction or enhance FM2 magnetization depending on the current density. Spin transfer devices are also known as spintronic devices and may have ferromagnetic (FM) layers with a perpendicular magnetic anisotropy (PMA) component where magnetization is aligned substantially perpendicular to the plane of the FM layer. These devices have an advantage over devices based on in-plane anisotropy in that they can satisfy the thermal stability requirement but also have less limits on cell aspect ratio. As a result, spintronic structures based on PMA are capable of scaling for higher packing density, which is a key challenge for future MRAM (Magnetoresistive Random Access Memory) and spin torque transfer (STT)-MRAM applications, and for other spintronic devices such as microwave generators and assist structures for PMR.

Related U.S. Pat. No. 10,424,326 discloses a magnetic flux guiding device that is a STRAMR approach. STRAMR devices typically require a high current density to flip a magnetization in a FM layer in the WG, and this issue is substantially overcome by placing spin polarization (SP) layers on each side of the FM layer so that an additive spin torque on the FM layer magnetization is generated to allow a reduced current density. However, a new assist design is desired that does not rely on spin flipping to enhance the write field, and has flexibility in increasing one or both of a local magnetic field and field gradient at the main pole/WG interface and at the WG/write shield interface thereby improving linear density and areal density capability.

SUMMARY

One objective of the present disclosure is to provide a PMR writer wherein a spin injection assisted magnetic recording (SIAMR) device is formed in a write gap (WG) and enables spin polarized electrons to flow into one or both of a write shield at a SIAMR/WS interface and into a MP at a MP/SIAMR interface thereby enhancing the return field and write field, respectively, to improve linear density and ADC.

A second objective of the present disclosure is to provide a SIAMR device according to the first objective that also provides improved reliability compared with conventional PMR writers with MAMR capability.

According to one embodiment of the present invention, these objectives are achieved with a PMR writer design wherein a SIAMR device comprises a FM layer and at least one adjoining spin preserving (SP) layer in the WG between a MP and a WS. In a first embodiment, the SIAMR device further includes a pair of so-called spin killing layers made of Ta, W, Pt, Ru, Ti, or Ir on a side of the FM layer that is opposite to the FM side that adjoins the SP layer. The SP layer contacts the WS, and applied current flows from the MP to WS so that spin polarized electrons from the FM layer provide a magnetization that enhances a local WS field proximate to the SP/WS interface and a return field in the WS. In an alternative embodiment, when the SP layer contacts the MP and applied current (I_(a)) flows from the WS through the FM layer and SP layer into the MP, I_(a) produces a magnetization that enhances a local MP field proximate to the MP/SP interface, and the write field. There are leads from the MP and WS that are connected to a direct current (dc) source to enable I_(a) to be applied across the SIAMR device during a write process.

According to a second embodiment, the features of the first embodiment are retained except the spin killing layers are replaced with a dielectric (WG) layer, and I_(a) is applied through a lead to the FM layer and across the SP layer to the WS. In both of the first and second embodiments, each of the FM and SP layers has a front side at the air bearing surface (ABS), and the SP layer has a backside at a WS throat height (TH). A backside of the FM layer is typically at a height substantially greater than the WS TH in the second embodiment. The FM layer may be a single layer or multilayer that is comprised of one or more of Fe, Co, CoFe, NiFe, CoFeNi, and alloys thereof such as CoB, FeB, CoFeB, and CoFeNiB, or alloys with one or more of Ta, Zr, and Cr such as CoTaZr. The SP layer is a material comprised of one or more of Cu, Au, Ag, Ru, Cr, and Al while the dielectric (WG) layer may be an oxide or nitride of Al, Mg, Si, Ti, Ta, Hf, or Zr.

A third embodiment retains all the features of the second embodiment except the backside of the SP layer is extended to a height greater than the WS TH to enable greater current density in the spin polarized current through the SP layer.

According to a fourth embodiment that is a modification of the third embodiment, a front side of the FM layer is recessed to the WS TH, for example, to allow lower current density between the FM and SP layers because greater overlap of the two layers is possible in the cross-track direction outside the tight confines of the WG proximate to the ABS. Therefore, improved reliability is expected since lower current density means lower risk of electromigration of metals or alloys within the FM and SP layers.

In a fifth embodiment, the dielectric layer adjoining one side of the FM layer in the fourth embodiment is replaced with a first SP layer (SP1) such that spin polarized current from the FM layer flows through SP1 to the MP and through a second SP layer (SP2) to the WS to enhance localized MP and localized WS magnetization, respectively, thereby improving the write field and return field. Optionally, one or both of the FM layer front side is at the ABS, and the SP1 and SP2 backsides are at the WS TH.

According to a sixth embodiment, any of the second through fifth embodiments is modified to use a stitched lead between the dc source and the FM layer. Thus, a back portion of the FM layer may be stitched to a SP material or to a spin killing material. As a result, the lead resistance is lowered, which in turn reduces operating temperature to improve reliability.

In the seventh embodiment, the FM layer in the second embodiment is omitted and the SP layer adjoins both of the WS and MP so that when I_(a) is applied from the MP to the WS, a portion of the MP proximate to the MP/SP interface serves as the FM layer, which spin polarizes I_(a). A first portion of the SP layer proximate to the MP trailing side is preferably recessed beyond the WS TH to avoid reducing MP magnetization proximate to the ABS, and a second portion of the SP layer adjoining the WS has a front side at the ABS, and a backside at the same height as the first portion.

A process sequence is also provided for forming a SIAMR stack of layers according to an embodiment of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a head arm assembly of the present disclosure.

FIG. 2 is side view of a head stack assembly of the present disclosure.

FIG. 3 is a plan view of a magnetic recording apparatus of the present disclosure.

FIG. 4 is a down-track cross-sectional view of a combined read-write head with leading and trailing loop pathways for magnetic flux return to the main pole in the PMR writer according to an embodiment of the present disclosure.

FIG. 5 is an ABS view of a SIAMR device according to a first embodiment of the present disclosure wherein a stack comprised of two spin killing layers, a FM layer, and a SP layer are formed on a MP trailing side and in a WG such that the SP layer adjoins a WS bottom surface.

FIG. 6A is a down-track cross-sectional view of the SIAMR device in FIG. 5 where a current I_(a) is applied from the MP and across the FM and SP layers to enhance a local WS magnetic field and WS return field.

FIG. 6B is an alternative first embodiment where the stacking order of SIAMR device layers in FIG. 6A is reversed, and I_(a) is applied from the TS and across the FM and SP layers to enhance a local MP magnetic field and write field.

FIG. 7 is a down-track cross-sectional view where the spin killing layers in FIG. 6A are replaced with a dielectric layer and I_(a) is injected into the FM layer and flows to the WS according to a second embodiment of the present disclosure.

FIG. 8 is a down-track cross-sectional view depicting a third embodiment of the present disclosure wherein a backside of the SP layer in FIG. 7 is extended beyond a WS throat height (TH), and I_(a) flows from the FM layer to WS.

FIG. 9 is a down-track cross-sectional view of a fourth embodiment of the present disclosure wherein a front side of the FM layer in FIG. 8 is recessed to a WS throat height.

FIG. 10 is a down-track cross-sectional view of a fifth embodiment of the present disclosure wherein a second SP layer is inserted between the FM layer and MP trailing side in FIG. 9 so that spin polarized current from the FM layer flows through both of the first and second SP layers to the WS and MP, respectively.

FIG. 11 is a down-track cross-sectional view showing a sixth embodiment of the present disclosure that is a modification of the fifth embodiment wherein the lead to the FM layer is stitched.

FIG. 12 is a down-track cross-sectional view depicting a seventh embodiment of the present disclosure wherein the FM layer in FIG. 9 is omitted, and the SP layer has a first portion adjoining the MP that has a recessed front side while a second portion of the SP layer contacting the WS has a front side at the ABS.

FIGS. 13A, 14A, 16A-18A and FIGS. 19-21 are ABS views that depict a sequence of steps in forming a SIAMR stack of layers between a MP trailing side and a WS according to an embodiment of the present disclosure.

FIGS. 13B, 14B, and 16B are down-track cross-sectional views of the intermediate structures shown in FIGS. 13A, 14A, and 16A, respectively, and FIG. 15 is a down-track cross-sectional view showing the patterning of a FM layer.

FIG. 17B is a top-down view of the intermediate structure shown in FIG. 17A that depicts a step of patterning a front portion of the SP layer according to an embodiment of the present disclosure.

FIG. 18B is a top-down view of the intermediate structure in FIG. 18A that depicts a step of forming a cross-track width in the SIAMR stack of layers according to an embodiment of the present disclosure.

DETAILED DESCRIPTION

The present disclosure is a PMR writer with a SIAMR design wherein spin polarized current is injected into a FM layer and then across at least one SP layer in a WG before entering a main pole or a write shield in order to improve linear density, reliability, and ADC. In the drawings, the y-axis is in a cross-track direction, the z-axis is in a down-track direction, and the x-axis is in a direction orthogonal to the ABS and towards a back end of the writer structure. Thickness refers to a down-track distance, width is a cross-track distance, and height is a distance from the ABS in the x-axis direction. The terms “downward” and “upward” when referring to write field and return field directional arrows in the drawings indicate a direction that is into the ABS and toward a back end of the PMR writer for “upward”, and out of the ABS and toward a magnetic medium for “downward”. The terms “MP field” and “write field” may be used interchangeably. Although the exemplary embodiments depict a single PMR writer, the present disclosure anticipates that two or more PMR writers may be formed on a slider and each of the PMR writers comprises a SIAMR device described herein.

Referring to FIG. 1, a head gimbal assembly (HGA) 100 includes a magnetic recording head 1 comprised of a slider and a PMR writer structure formed thereon, and a suspension 103 that elastically supports the magnetic recording head. The suspension has a plate spring-like load beam 222 formed with stainless steel, a flexure 104 provided at one end portion of the load beam, and a base plate 224 provided at the other end portion of the load beam. The slider portion of the magnetic recording head is joined to the flexure, which gives an appropriate degree of freedom to the magnetic recording head. A gimbal part (not shown) for maintaining a posture of the magnetic recording head at a steady level is provided in a portion of the flexure to which the slider is mounted.

HGA 100 is mounted on an arm 230 formed in the head arm assembly 103. The arm moves the magnetic recording head 1 in the cross-track direction y of the magnetic recording medium 140. One end of the arm is mounted on base plate 224. A coil 231 that is a portion of a voice coil motor is mounted on the other end of the arm. A bearing part 233 is provided in the intermediate portion of arm 230. The arm is rotatably supported using a shaft 234 mounted to the bearing part 233. The arm 230 and the voice coil motor that drives the arm configure an actuator.

Next, a side view of a head stack assembly (FIG. 2) and a plan view of a magnetic recording apparatus (FIG. 3) wherein the magnetic recording head 1 is incorporated are depicted. The head stack assembly 250 is a member to which a first HGA 100-1 and second HGA 100-2 are mounted to arms 230-1, 230-2, respectively, on carriage 251. A HGA is mounted on each arm at intervals so as to be aligned in the perpendicular direction (orthogonal to magnetic medium 140). The coil portion (231 in FIG. 1) of the voice coil motor is mounted at the opposite side of each arm in carriage 251. The voice coil motor has a permanent magnet 263 arranged at an opposite position across the coil 231.

With reference to FIG. 3, the head stack assembly 250 is incorporated in a magnetic recording apparatus 260. The magnetic recording apparatus has a plurality of magnetic media 140 mounted to spindle motor 261. For every magnetic recording medium, there are two magnetic recording heads arranged opposite one another across the magnetic recording medium. The head stack assembly and actuator except for the magnetic recording heads 1 correspond to a positioning device, and support the magnetic recording heads, and position the magnetic recording heads relative to the magnetic recording medium. The magnetic recording heads are moved in a cross-track of the magnetic recording medium by the actuator. The magnetic recording head records information into the magnetic recording media with a PMR writer element (not shown) and reproduces the information recorded in the magnetic recording media by a magnetoresistive (MR) sensor element (not shown).

Referring to FIG. 4, magnetic recording head 1 comprises a combined read-write head. The down-track cross-sectional view is taken along a center plane (44-44 in FIG. 5) formed orthogonal to the ABS 30-30, and that bisects the main pole layer 14. The read head is formed on a substrate 81 that may be comprised of AlTiC (alumina+TiC) with an overlying insulation layer 82 that is made of a dielectric material such as alumina. The substrate is typically part of a slider formed in an array of sliders on a wafer. After the combined read head/write head is fabricated, the wafer is sliced to form rows of sliders. Each row is typically lapped to afford an ABS before dicing to fabricate individual sliders that are used in a magnetic recording device. A bottom shield 84 is formed on insulation layer 82.

A magnetoresistive (MR) element also known as MR sensor 86 is formed on bottom shield 84 at the ABS 30-30 and typically includes a plurality of layers (not shown) including a tunnel barrier formed between a pinned layer and a free layer where the free layer has a magnetization (not shown) that rotates in the presence of an applied magnetic field to a position that is parallel or antiparallel to the pinned layer magnetization. Insulation layer 85 adjoins the backside of the MR sensor, and insulation layer 83 contacts the backsides of the bottom shield and top shield 87. The top shield is formed on the MR sensor. An insulation layer 88 and a top shield (S2B) layer 89 are sequentially formed on the top magnetic shield. Note that the S2B layer 89 may serve as a flux return path (RTP) in the write head portion of the combined read/write head. Thus, the portion of the combined read/write head structure formed below layer 89 in FIG. 4 is typically considered as the read head. In other embodiments (not shown), the read head may have a dual reader design with two MR sensors, or a multiple reader design with multiple MR sensors.

The present disclosure anticipates that various configurations of a write head may be employed with the read head portion. In the exemplary embodiment, magnetic flux known as write field 70 in main pole (MP) layer 14 is generated with flowing a write current (Iw) through bucking coil 80 b and driving coil 80 d that are below and above the MP layer, respectively, and are connected by interconnect 51. Magnetic flux 70 exits the MP layer at pole tip 14 p at the ABS 30-30 and is used to write a plurality of bits on magnetic media 140. Magnetic flux 70 b returns to the MP through a trailing loop comprised of trailing shields 17, 18, PP3 shield 26, and top yoke 18 x. There is also a leading return loop for magnetic flux 70 a that includes leading shield 11, leading shield connector (LSC) 33, S2 connector (S2C) 32, return path 89, and back gap connection (BGC) 62. The magnetic core may also comprise a bottom yoke 35 below the MP layer. Dielectric layers 10, 13, 36-39, and 47-49 are employed as insulation layers around magnetic and electrical components. A protection layer 27 covers the PP3 trailing shield and is made of an insulating material such as alumina. Above the protection layer and recessed a certain distance u from the ABS 30-30 is an optional cover layer 29 that is preferably comprised of a low coefficient of thermal expansion (CTE) material such as SiC. Overcoat layer 28 is formed as the uppermost layer in the write head.

Referring to FIG. 5, an ABS view is depicted of the PMR writer in FIG. 4 according to an embodiment of the present disclosure. The main pole (MP) has a MP tip 14 p with track width w, trailing side 14 t 1, leading side 14 b 1, and two sides 14 s formed equidistant from a center plane 44-44 in an All Wrap Around (AWA) shield structure. There is a write gap 16 with thickness t on the MP trailing side, side gaps 15 adjoining each MP side, and a leading gap 13 below the MP leading side. Leading shield 11 contacts the leading gap and a bottom surface of side shields 12 at plane 42-42. Side shields (SS) have an inner side 12 s adjoining a side gap, and far sides 60, 61 at an outer side of the AWA shield structure. The trailing shield (TS) structure comprises a first trailing shield hereinafter referred to as the write shield (WS) 17 with a magnetic saturation value from 19 kiloGauss (kG) to 24 kG, and with a bottom surface 17 b on the WG except over a SIAMR stack of layers 2-6 each having a width ≤½ w on each side of the center plane. WS sides 17 s are formed coplanar with WG sides 16 s on each side of the center plane. The TS structure also includes a second TS 18 formed on the WS top surface and sides 17 t and 17 s, respectively, on WG sides 16 s, and on a top surface of the side shields 12 at plane 41-41. Plane 41-41 includes the MP trailing side at the ABS. Plane 42-42 is parallel to plane 41-41, and includes the MP leading side at the ABS. Each of the SS, leading shield, TS structure, and MP are comprised of one or more of CoFe, NiFe, and CoFeNi.

According to a first embodiment of the present disclosure, the SIAMR stack of layers has a first spin killing (SK) layer 2, non-magnetic spacer 3, second SK layer 4, FM layer 5, and spin preserving (SP) layer 6 sequentially formed on MP trailing side 14 t 1. The SIAMR stack of layers has thickness t equivalent to that of WG layer 16 between plane 41-41 and WS 17, and a width that is typically ≤w. Each SK layer is also known as a non-spin preserving layer and prevents spin polarized electrons from the FM layer from reaching the MP trailing side, and is preferably one of Ta, W, Pt, Ru, Ti, Ir, or Cr. The non-magnetic spacer is comprised of Ta, Ru, W, or Cr, and serves to improve the growth of the FM layer for better magnetic properties. The FM layer may be a single layer or multilayer that is comprised of one or more of Fe, Co, CoFe, NiFe, CoFeNi, and alloys thereof such as CoB, FeB, CoFeB, and CoFeNiB, or alloys with one or more of Ta, Zr, Re, and Mo. The SP layer is non-magnetic and comprises one or more of Cu, Au, Ag, Ru, Cr, and Al, and is responsible for having sufficient spin diffusion length to allow spin polarized electrons (not shown) to substantially remain in their original orientation while traversing from the FM layer to WS 17 (and to MP 14 in the fifth and sixth embodiments described later).

The first embodiment is a modification of the spin flipping element disclosed in related U.S. Pat. No. 10,325,618. We have discovered that by replacing a single SK layer with a stack comprised of a non-magnetic spacer 3 between two SK layers 2 and 4 in the SIAMR stack of layers, performance characteristics including electrical conductivity, thermal conductivity, electro-thermal robustness, and magnetic damping properties are simultaneously optimized.

Referring to FIG. 6A, a down-track cross-sectional view of the first embodiment is shown where the SIAMR stack of layers 2-6 is formed between MP 14 and WS 17. First SK layer 2 forms a first interface that is also referred to as the MP/SK interface with MP trailing side 14 t 1, and SP layer 6 forms a second interface also known as the SP/WS interface with WS bottom surface 17 b. MP local magnetization 14 m that is adjacent to the MP/SK interface is generally in the direction of the write gap field flux (H_(WG)), which is from the MP trailing side to WS bottom surface. There is also a local WS magnetization 17 m adjacent to the SP/WS interface that is substantially parallel to H_(WS). Moreover, FM layer 5 has magnetization 5 m substantially parallel to H_(WS). Other layers in the PMR writer are omitted in order to focus on the path of applied current I_(a) while writing a transition where write field 70 is oriented downward at the ABS 30-30 and into a magnetic medium (not shown), and where return field 70 b is orthogonal to the ABS and upward into the WS. In the exemplary embodiment, each of the SIAMR stack of layers has a front side at the ABS, and a backside at a WS throat height h where the WS bottom surface connects with WS side 17 s. Thus, front sides 5 f and 6 f of the FM layer and SP layer, respectively, are coplanar, and FM layer backside 5 e and SP layer backside 6 e are at height h. Lead 57 carries I_(a) into MP 14 from direct current (dc) source 50 while lead 58 carries I_(a) back to the dc source from TS 17. In other embodiments (not shown), the SIAMR stack of layers may have a backside at a height unequal to h.

A key feature is that when I_(a) flows from the MP 14 to WS 17, spin polarized current from FM layer 5 traverses the SP layer 6 and enters the WS, and produces a magnetization (not shown) proximate to the SP/WS interface that enhances local WS magnetization 17 m and return field 70 b. I_(a) current density is less than required to flip FM magnetization 5 m in STRAMR devices. Therefore, improved reliability is realized because of a reduced risk of electromigration within the SIAMR metal or alloy layers. During a transition (not shown) when the write field is orthogonal to the ABS 30-30 and upward into the MP, and the directions of I_(a), magnetizations 5 m, 14 m, and 17 m, and return field 70 b are reversed, there is no spin torque applied to local MP magnetization 14 m because SK layers 2 and 4 prevent spin polarized electrons from reaching the MP.

An alternative first embodiment is depicted in FIG. 6B where the SIAMR layers are formed in reverse stacking order on MP trailing side 14 t 1 such that SP layer 6 adjoins the MP trailing side and forms a MP/SP interface while SK layer 2 contacts the WS bottom surface 17 b and forms a SK/WS interface. This reverse SIAMR configuration is advantageous for boosting write field 70 during a transition when the write field is oriented orthogonal to the ABS 30-30 and into the MP 14, and when I_(a) is applied from the WS to MP. Here, local MP magnetization 14 m, FM magnetization 5 m, local WS magnetization 17 m, and return field 70 b are also opposite to the direction shown in FIG. 6A. In this case, spin polarized current from FM layer 5 traverses the SP layer and enters the MP to generate a magnetization adjacent to the MP trailing side that enhances the local MP magnetization 14 m, and write field 70 that is in an upward direction. When the write field is reversed and I_(a) is applied from the MP to WS, there is no spin torque produced on WS magnetization 17 m because of the presence of SK layers 2, 4 that prevent spin polarized electrons from reaching WS bottom surface 17 b.

Referring to FIG. 7, a second embodiment of the present disclosure is depicted and is a modification of the first embodiment where SK layers 2 and 4, and spacer 3 are replaced with WG layer 16 that is a dielectric material. Furthermore, current I_(a) is injected through lead 57 and then into a contact 59 before entering the FM layer 5 since there is no longer a conductive pathway from MP 14 to the FM layer. The FM layer backside 5 e is now at a height substantially greater than height h1 where the MP tapered trailing side 14 t 1 connects with MP top surface 14 t 2 at corner 14 c. Thus, the FM layer has a bottom surface 5 b that faces the MP and is separated from MP trailing side by WG layer 16, and from MP top surface by insulation layer 47. FM layer top surface 5 t adjoins contact 59 proximate to end 5 e. Otherwise, all aspects of the SP layer 6 are retained from the first embodiment in FIG. 6A including a front side 6 f at the ABS 30-30, and a backside 6 e at the WS TH, which is height h. Accordingly, spin polarized electrons from the FM layer traverse SP layer 6 and generate magnetization that enhances local WS magnetization 17 m proximate to the SP/WS interface, and return field 70 b when write field 70 is out of the MP and orthogonal to the ABS 30-30, and the return field is in an upward direction. Again, linear density and ADC are improved. When writing a transition where the write field, return field, I_(a), and magnetizations 14 m, 5 m, and 17 m are reversed, there is no enhancement to the write field because the WG layer prevents spin polarized electrons from reaching the MP trailing side.

Referring to FIG. 8, a third embodiment of the present disclosure is illustrated and is a modification of the second embodiment in FIG. 7 where SP layer backside 6 e is extended farther from the ABS 30-30 to a height h2 where h2>h. The additional height of the SP layer 6 between front side 6 f and backside 6 e is expected to allow more spin polarized current from the FM layer 5 to the SP/WS interface thereby generating greater magnetization to further enhance WS magnetization 17 m and write field 70 b (with the same current density in FM layer 5) compared with the SIAMR structure in FIG. 7. Optionally, less current density (same total current) in the FM layer produces an equal amount of magnetization to enhance WS magnetization and return field compared with previous embodiments to improve device reliability. Otherwise, all features and advantages of the second embodiment are retained in the third embodiment.

In FIG. 9, a fourth embodiment of the present disclosure is shown where the SIAMR structure in FIG. 8 is modified by recessing FM layer front side 5 f to height h. Thus, WG layer 16 fills the entire space between the ABS 30-30 and FM layer front side, and SP layer 6 is the only SIAMR layer exposed at the ABS and in contact with WS 17. This design is expected to allow lower current density between the FM layer 5 and SP layer since this scheme allows a greater overlap of the aforementioned layers in the cross-track direction in embodiments where there is a larger WG cavity (not shown) at a height greater than h than between the ABS and the WS TH at height h. As a result, there is a significant improvement in reliability at the same performance compared with earlier embodiments where the write field 70 is in a downward direction out of the ABS, the return field 70 b is upward from the ABS, and I_(a) is from the FM layer and across the SP layer into the WS 17 to enhance local WS magnetization 17 m and the return field.

Referring to FIG. 10, a fifth embodiment of the present disclosure is depicted and is a modification of the embodiment in FIG. 9 where a portion of the WG layer 16 adjoining MP trailing side 14 t 1 is replaced with a first SP layer (SP1) 6 a having a backside 6 e 1 at height h2, and a front side 6 f 1 at the ABS 30-30. Thus, the SP1 forms a MP/SP1 interface with the MP trailing side, and adjoins a portion of FM layer bottom surface 5 b. The second SP layer (SP2) 6 b (former SP layer 6 in FIG. 9) contacts a portion of FM layer top surface 5 t, and forms a SP2/WS interface with WS bottom surface 17 b. The SP2 has a front side 6 f 2 at the ABS, and a backside 6 e 2 at height h2. There is a first return lead 58 a between TS 17 and dc source 50 that carries current I_(b), and a second return lead 58 b between MP 14 and the dc source that carries I_(a). In this embodiment, lead 57 is connected to contact 59, which injects (I_(a)+I_(b)) from the dc source to FM layer 5. In alternative embodiments (not shown) where the FM layer front side 5 f is moved forward to the ABS, one or both of SP1 and SP2 backsides 6 e 1 and 6 e 2, respectively, may also be moved forward to height h, or maintained at height h2.

An advantage of the SIAMR layout in the fifth embodiment compared with previous embodiments is that write field 70 and return field 70 b are simultaneously enhanced as a result of spin polarized current from FM layer 5 through SP1 6 a and into MP tip 14 p to generate magnetization (not shown) that enhances local MP magnetization 14 m and the write field, and from the FM layer through SP2 6 b and into WS 17 to produce magnetization that increases local WS magnetization 17 m and the return field.

Note that the fifth embodiment provides similar benefits when the direction of the write field 70, return field 70 b, and magnetizations 5 m, 14 m, and 17 m are reversed (not shown) because I_(a) and I_(b) are maintained in the same direction. Thus, spin polarized electrons traversing through SP1 6 a from FM layer 5 will continue to enhance local MP magnetization 14 and the write field, and spin polarized current through SP2 6 b will continue to increase local WS magnetization 17 m and the return field.

Referring to FIG. 11, a sixth embodiment of the present disclosure is shown that is a modification of the fifth embodiment where SP1 and SP2 front sides 6 f 1 and 6 f 2, respectively, as well as FM layer front side 5 f are at the ABS 30-30, and where SP1 and SP2 backsides 6 e 1 and 6 e 2, respectively, are at height h2. A key feature is that lead 57 from the dc source 50 to FM layer 5 in FIG. 10 is now stitched and comprised of a SP material or spin killing material in stitched layer 7 having one end at contact 59, and an opposite end that overlaps a top surface 5 t of the FM layer proximate to end 5 e. Accordingly, a portion of stitched layer bottom surface 7 b adjoins the FM layer top surface. The stitched lead is advantageously employed to reduce the lead resistance and thereby lower temperature in the SIAMR device to improve reliability. It should be understood that the lead modification described for the sixth embodiment may be applied to any of the second through fifth embodiments with similar benefits. In alternative embodiments (not shown) where the FM layer has a front side at the ABS, one or both of SP1 6 a and SP2 6 b may have a backside at height h.

According to a seventh embodiment shown in FIG. 12, the SIAMR device in FIG. 7 is modified with the removal of FM layer 5 such that a single SP layer extends from the MP trailing side 14 t 1 to the WS bottom surface 17 b. Thus, a first portion 6 a of the SP layer has a recessed front side 6 f 1 at height r that may be proximate to the WS TH, a backside 6 e at height h2, and forms a MP/SP interface with MP trailing side. Preferably, height r is from 1 nm to 20 nm and slightly larger than the effective throat height on the trailing shield, and h2 can be from 10 to 200 nm larger than r from the ABS 30-30. In the exemplary embodiment, the MP trailing side connects with MP top surface 14 t 2 at corner 14 c that is at height h1 from the ABS where h1>h2. A second portion 6 b of the SP layer has backside 6 e at height h2, a front side 6 f 2 at the ABS, adjoins first portion 6 a between height r and height h2, and forms a SP/WS interface with WS bottom surface 17 b. The first portion of SP layer is recessed from the ABS so that local MP magnetization 14 m proximate to the ABS is not reduced. Note that lead 57 now connects dc source 50 with MP 14. Here, the MP proximate to the MP trailing side serves as the FM layer which spin polarizes I_(a) that flows from the MP and across the SP layer and into the WS 17. Similar to previous embodiments, the spin polarized electrons produce a magnetization proximate to the WS bottom surface that enhances local WS magnetization 17 m and return field 70 b.

For all embodiments, the advantage of injecting spin polarized electrons from the FM layer across the SP layer and into one or both of the MP and WS generates magnetization at the MP/SP interface and SP/WS interface, respectively, that increases local magnetization at one or both of the interfaces and enhances one or both of the write field and return field depending on the direction of the current flow (except in the fifth and sixth embodiments). As a result, the PMR writer has improved performance based on greater linear density and higher ADC. Furthermore, a PMR writer having a SIAMR structure in the WG is expected to exhibit greater reliability because a lower current density for I_(a) is required than in PMR writers employing a STRAMR device in the WG.

A process sequence for fabricating a magnetic flux guiding device in a WG and with a front side at the ABS has been described in related U.S. Pat. No. 10,424,326. A similar sequence of steps may be used to form a SIAMR stack of layers having a width w in a WG, and a backside at a WS TH as shown in the first embodiment.

A process sequence for fabricating the SIAMR device of the second through fourth embodiments is illustrated starting at FIG. 13A. The partially formed writer structure including MP tip 14 p that adjoins side gaps 15 and leading gap 13 is provided according to a conventional process sequence. Side shield top surfaces 12 t are coplanar with a trailing edge of the MP tapered trailing side 14 t 1 at plane 41-41, which is slightly offset from being orthogonal to the subsequently formed ABS plane. FIG. 13B shows the down-track cross-sectional view at plane 44-44 in FIG. 13A. MP tapered trailing side 14 t 1 has a taper angle δ (generally greater than 0 degrees) and is coplanar with a tapered front side 47 f of insulation layer 47 made of Al₂O₃ or SiO₂ that is formed on MP top surface 14 t 2. Tapered front side connects with dielectric layer top surface 47 t that is above and essentially parallel to the MP top surface. Note that the eventual ABS, hereinafter referred to as ABS plane 30-30, is not determined until a lapping process is performed after all layers in the PMR writer structure are formed.

Referring to FIG. 14A, the next step in the fabrication process is sequential deposition of WG layer 16 and FM layer 5 on MP tapered trailing side 14 t 1. FIG. 14B shows that the WG layer and FM layer continue toward a back end of the writer structure and are also formed on insulation layer 47.

As shown in FIG. 15, a first photoresist layer is coated on FM layer 5, and then exposed with the use of a chrome on quartz mask, for example, and developed with a photolithography process to form photoresist mask 52 having a front side 52 f that is recessed to height h from the ABS plane 30-30 and thereby forming an opening 53 a that exposes a portion of FM layer top surface 5 t. Note that opening 53 a may be omitted when forming a FM layer with a front side at the ABS as in the second and third embodiments. A second opening 53 b is also formed during the photoresist patterning process. As a result, photoresist mask backside 52 e is formed above MP top surface 14 t 2, and will be used to define a FM layer backside in a subsequent step.

In FIG. 16A, an ABS view is shown after a reactive ion etch (RIE) or ion beam etch (IBE) process is employed to transfer openings 53 a, 53 b through the FM layer 5 and stop on WG layer top surface 16 t. Thereafter, photoresist mask 52 is removed by a conventional method. FIG. 16B depicts a down-track cross-sectional view of the intermediate structure in FIG. 16A. The FM layer now has a front side 5 f that is recessed to height h from the ABS plane 30-30, and a backside 5 e above MP top surface 14 t 2.

Referring to FIG. 17A, an additional WG layer 16 a is optionally deposited on exposed portions of WG layer 16 between FM layer front side 5 f and the ABS plane, and behind FM layer backside 5 e. In the exemplary embodiment, the WG layers 16, 16 a are made of the same dielectric material and shown hereinafter as a single WG layer 16. Then, SP layer 6 is deposited on the FM layer (not shown) and on the WG layer. A sputter deposition or ion beam deposition tool may be used to deposit each SIAMR layer including the FM layer 5 and SP layer. A second photoresist is coated and then exposed with the aid of another mask and developed by a photolithography process to yield photoresist mask 54 having a full width w1 between sides 54 s that are coplanar with sides 60, 61 of the AWA shield structure described previously.

FIG. 17B shows a top-down view of the intermediate structure in FIG. 17A where the underlying MP has sides indicated by the dashed line 14 s. Dashed line 14 x is between corners 14 c and represents the interface where the MP tip portion 14 p adjacent to the MP trailing side 14 t 1 meets the back portion of MP 14 below MP top surface 14 t 2. Corner 14 c is also shown in a down-track cross-sectional view in FIG. 9. Returning to FIG. 17B, backside 54 b of the second photoresist mask 54 is at height h2 where h2>h and will be used in a later step to define a backside of SP layer 6. Photoresist mask front side 54 f may be at the ABS plane 30-30 or on an opposite side (not shown) of the ABS plane with respect to backside 54 b.

FIG. 18A depicts the intermediate structure in FIG. 17A after a RIE or IBE step is performed to transfer the shape in second photoresist mask 54 through exposed portions of SP layer 6 and stopping on FM layer 5 thereby forming a SP layer backside 6 e at height h2 (FIG. 18B). The resulting opening (not shown) behind the SP layer is refilled with WG layer 16. The second photoresist mask is removed. Next, a third photoresist is coated and then exposed with a new mask and developed to form a third photoresist mask 56 having width w and sides 56 s that are equidistant from center plane 44-44. Openings 55 are formed that expose portions of SP layer top surface 6 t 1 at distances greater than ½ w from the center plane. Photoresist mask front side 56 f may be on an opposite side of plane 30-30 than MP sides 14 s since the ABS is not determined until a lapping process at the end of the fabrication sequence.

Referring to FIG. 19, a RIE or IBE process is performed to transfer openings 55 through exposed portions of WG layer 16, and FM layer 5 before stopping on SS top surface 12 t and side gap 15 on each side of center plane 44-44. As a result, SP layer 6 has a constant width w from plane 30-30 to a backside (not shown) at height h2, and FM layer 5 has width w from front side that is at height h to a backside 5 e described earlier. Thereafter, WG layer 16 is deposited on SS top surface and the side gap to thickness t. The third photoresist mask is removed with a conventional method.

Referring to FIG. 20, WS 17 is deposited on WG layer 16 and on SP layer 6. Next, a fourth photoresist layer is coated on the WS and is exposed with a fourth mask and developed to generate a fourth photoresist mask 58 having width w2 where w2>w, and sides 58 s that are equidistant from center plane 44-44. Openings 57 adjacent to sides 58 s expose a portion of WS top surface 17 t.

FIG. 21 depicts the intermediate structure in FIG. 20 after a RIE or IBE is performed to transfer openings 57 through WS 17 and WG layer 16, and stopping on SS top surface 12 t. After the fourth photoresist mask is removed with a conventional process, the second TS 18 is plated on SS top surface 12 t, WS top surface 17 t, and adjoins WG sides 16 s and WS 17 s. Thereafter, a well known sequence of steps is followed to form overlying layers in the PMR writer. Finally, a lapping step is used to form the ABS at plane 30-30 described previously.

While the present disclosure has been particularly shown and described with reference to, the preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made without departing from the spirit and scope of this disclosure. 

I claim:
 1. A spin injection assisted magnetic recording (SIAMR) structure, comprising: (a) a main pole (MP) that is configured to generate a magnetic (write) field which is directed orthogonal to an air bearing surface (ABS) and through a MP tip at the ABS; (b) a write shield (WS) with a side at the ABS through which a return field passes orthogonal to the ABS, and having a bottom surface that faces a MP trailing side; and (c) a SIAMR stack of layers formed in a write gap (WG) wherein a first layer contacts the WS bottom surface, and a second layer contacts the MP trailing side, wherein the SIAMR stack of layers comprises: (1) a ferromagnetic (FM) layer having a magnetization substantially in a direction of a WG field flux between the MP and WS, and wherein the FM layer has a front side at the ABS and a back side at a height substantially greater than a height of a backside of a spin preservation (SP) layer that adjoins a first side of the FM layer; (2) the SP layer that is either the first layer that conducts spin polarized current from the FM layer into the WS at the WS bottom surface, or is the second layer that conducts spin polarized current from the FM layer into the MP trailing side, and wherein the SIAMR stack of layers is configured so that when a current (Ia) is injected from a source into the FM layer through a lead that excludes the MP and TS, spin polarized electrons flow across the SP layer to generate a magnetization proximate to the MP trailing side that enhances a local MP magnetization and the write field when the SP layer is the second layer, or produces a magnetization proximate to the WS bottom surface that enhances a local WS magnetization and the return field when the SP layer is the first layer; and (3) the other of the first layer or second layer that contacts a second side of the FM layer opposite to the FM layer first side, and does not allow spin polarized current to flow to the MP or TS.
 2. The SIAMR structure of claim 1 wherein the FM layer is a single layer or multilayer comprised of one or more of Fe, Co, CoFe, NiFe, CoFeNi, and alloys thereof including CoB, FeB, CoFeB, and CoFeNiB, or alloys with one or more of Ta, Zr, Re, and Mo.
 3. The SIAMR structure of claim 1 wherein the SP layer is one or more of Cu, Au, Ag, Ru, Cr, and Al.
 4. A head gimbal assembly (HGA), comprising: (a) a magnetic recording head that comprises the SIAMR structure of claim 1; and (b) a suspension that elastically supports the magnetic recording head, wherein the suspension has a flexure to which the magnetic recording head is joined, a load beam with one end connected to the flexure, and a base plate connected to the other end of the load beam.
 5. A magnetic recording apparatus, comprising: (a) the HGA of claim 4; (b) a magnetic recording medium positioned opposite to a slider; (c) a spindle motor that rotates and drives the magnetic recording medium; and (d) a device that supports the slider, and that positions the slider relative to the magnetic recording medium.
 6. The SIAMR structure of claim 1 wherein the SP layer has a backside at a WS throat height (TH).
 7. The SIAMR structure of claim 1 wherein the second layer is a dielectric (WG) layer.
 8. The SIAMR structure of claim 1 further comprised of a contact on the FM layer, wherein the contact connects the FM layer to the lead from the source. 